Project description:The Aurora kinases comprise an evolutionarily conserved protein family that is required for a variety of cell division events, including spindle assembly, chromosome segregation, and cytokinesis. Emerging evidence suggests that once phosphorylated, a subset of Aurora substrates can enhance Aurora kinase activity. Our previous work revealed that the Caenorhabditis elegans Tousled-like kinase TLK-1 is a substrate and activator of the AIR-2 Aurora B kinase in vitro and that partial loss of TLK-1 enhances the mitotic defects of an air-2 mutant. However, given that these experiments were performed in vitro and with partial loss of function alleles in vivo, a necessary step forward in our understanding of the relationship between the Aurora B and Tousled kinases is to prove that TLK-1 expression is sufficient for Aurora B activation in vivo. Here, we report that heterologous expression of wild-type and kinase-inactive forms of TLK-1 suppresses the lethality of temperature-sensitive mutants of the yeast Aurora B kinase Ipl1. Moreover, kinase-dead TLK-1 associates with and augments the activity of Ipl1 in vivo. Together, these results provide critical and compelling evidence that Tousled has a bona fide kinase-independent role in the activation of Aurora B kinases in vivo.

Project description:In this study on human Tousled-Like-Kinase 2 (TLK2) mass spectrometry-based analysis was applied as part of a molecular characterization of TLK2 in the aim to increase the understanding of the mode of activation of this protein. Specifically, different TLK2 constructs were analyzed to generate a “phosphorylation map” of the TLK2 protein. To analyse the phosphorylation state of TLK2 we used recombinant protein purified from Escherichia coli. Samples of different TLK2 constructs were used for in-gel digestion and analysed by mass spectrometry. All samples were prepared and run in triplicates for label-free quantification. Explanation for MS raw files with TLK2 construct included: Ac: TLK2 construct consisting of amino acid residues 191-772 (Ac indicates active form). KD: TLK2 construct consisting of amino acid residues 191-772 with mutation D613A (KD indicates kinase-dead form). FusionKD: Kinase-dead part of a heterodimeric TLK2 construct (amino acid residues 191-772) with mutation D613A (KD indicates kinase-dead form). FusionAC: Active part of a heterodimeric TLK2 construct (amino acid residues 191-772) (Ac indicates kinase-dead form). KDlong: Kinase domain of TLK2 with C-tail (amino acid residues 450-772). KDshort: Kinase domain of TLK2 without C-tail (amino acid residues 450-753).

Project description:In this study on human Tousled-Like-Kinase 2 (TLK2) mass spectrometry-based analysis was applied as part of a molecular characterization of TLK2 in the aim to increase the understanding of the mode of activation of this protein. Specifically, different TLK2 constructs were expressed analyzed to generate a “phosphorylation map” of the TLK2 protein. To analyse the phosphorylation state of TLK2 we used recombinant protein purified from HEK293. Samples of different TLK2 constructs were used for in-gel digestion and analysed by mass spectrometry. All samples were prepared and run in triplicates for label-free quantification. Explanation for MS raw files with TLK2 construct included: KD: Kinase-dead TLK2 construct with mutation D613A, N-terminal His- and Strep-tag. wt: Active form of TLK2, canonical sequence, N-terminal His- and Strep-tag. full: Full-length canonical sequence (1-772), N-terminal His- and Strep-tag. trunc: Truncated TLK2 sequence (191-772), N-terminal His- and Strep-tag.

Project description:Tank-binding kinase (TBK)1 plays a central role in innate immunity: it serves as an integrator of multiple signals induced by receptor-mediated pathogen detection and as a modulator of IFN levels. Efforts to better understand the biology of this key immunological factor have intensified recently as growing evidence implicates aberrant TBK1 activity in a variety of autoimmune diseases and cancers. Nevertheless, key molecular details of TBK1 regulation and substrate selection remain unanswered. Here, structures of phosphorylated and unphosphorylated human TBK1 kinase and ubiquitin-like domains, combined with biochemical studies, indicate a molecular mechanism of activation via transautophosphorylation. These TBK1 structures are consistent with the tripartite architecture observed recently for the related kinase IKK?, but domain contributions toward target recognition appear to differ for the two enzymes. In particular, both TBK1 autoactivation and substrate specificity are likely driven by signal-dependent colocalization events.

Project description:Epidermal growth factor receptor (EGFR) is a target of signal-derived H2O2, and oxidation of active-site cysteine 797 to sulfenic acid enhances kinase activity. Although a major class of covalent drugs targets C797, nothing is known about its catalytic importance or how S-sulfenylation leads to activation. Here, we report the first detailed functional analysis of C797. In contrast to prior assumptions, mutation of C797 diminishes catalytic efficiency in vitro and cells. The experimentally determined pKa and reactivity of C797 toward H2O2 correspondingly distinguish this residue from the bulk of the cysteinome. Molecular dynamics simulation of reduced versus oxidized EGFR, reinforced by experimental testing, indicates that sulfenylation of C797 allows new electrostatic interactions to be formed with the catalytic loop. Finally, we show that chronic oxidative stress yields an EGFR subpopulation that is refractory to the FDA-approved drug afatinib. Collectively, our data highlight the significance of redox biology to understanding kinase regulation and drug pharmacology.

Project description:The conversion of PIP2 to PIP3 by phosphoinositide 3-kinase γ (PI3Kγ) is a critical step in neutrophil chemotaxis and is essential for metastasis in many types of cancer. PI3Kγ is activated via directed interaction with Gβγ heterodimers released from cell-surface G protein-coupled receptors (GPCRs) responding to extracellular signals. To resolve how Gβγ activates PI3Kγ, we determined cryo-EM reconstructions of PI3Kγ-Gβγ complexes in the presence of various substrates/analogs, revealing two distinct Gβγ binding sites, one on the p110γ helical domain and one on the C-terminal domain of the p101 subunit. Comparison of these complexes with structures of PI3Kγ alone demonstrates conformational changes in the kinase domain upon Gβγ binding similar to those induced by Ras·GTP. Assays of variants perturbing the two Gβγ binding sites and interdomain contacts that change upon Gβγ binding suggest that Gβγ not only recruits the enzyme to membranes but also allosterically controls activity via both sites. Studies in a zebrafish model examining neutrophil migration are consistent with these results. These findings set the stage for future detailed investigation of Gβγ-mediated activation mechanisms in this enzyme family and will aid in developing drugs selective for PI3Kγ.

Project description:RNA silencing is an evolutionarily conserved mechanism triggered by double-stranded RNA that is processed into 21- to 24-nt small interfering (si)RNA or micro (mi)RNA by RNaseIII-like enzymes called Dicers. Gene regulations by RNA silencing have fundamental implications in a large number of biological processes that include antiviral defense, maintenance of genome integrity and the orchestration of cell fates. Although most generic or core components of the various plant small RNA pathways have been likely identified over the past 15 years, factors involved in RNAi regulation through post-translational modifications are just starting to emerge, mostly through forward genetic studies. A genetic screen designed to identify factors required for RNAi in Arabidopsis identified the serine/threonine protein kinase, TOUSLED (TSL). Mutations in TSL affect exogenous and virus-derived siRNA activity in a manner dependent upon its kinase activity. By contrast, despite their pleiotropic developmental phenotype, tsl mutants show no defect in biogenesis or activity of miRNA or endogenous trans-acting siRNA. These data suggest a possible role for TSL phosphorylation in the specific regulation of exogenous and antiviral RNA silencing in Arabidopsis and identify TSL as an intrinsic regulator of RNA interference.

Project description:Potassium channels that are inhibited by internal ATP (K(ATP) channels) provide a critical link between metabolism and cellular excitability. Protein kinase C (PKC) acts on K(ATP) channels to regulate diverse cellular processes, including cardioprotection by ischemic preconditioning and pancreatic insulin secretion. PKC action decreases the Hill coefficient of ATP binding to cardiac K(ATP) channels, thereby increasing their open probability at physiological ATP concentrations. We show that PKC similarly regulates recombinant channels from both the pancreas and heart. Surprisingly, PKC acts via phosphorylation of a specific, conserved threonine residue (T180) in the pore-forming subunit (Kir6.2). Additional PKC consensus sites exist on both Kir and the larger sulfonylurea receptor (SUR) subunits. Nonetheless, T180 controls changes in open probability induced by direct PKC action either in the absence of, or in complex with, the accessory SUR1 (pancreatic) or SUR2A (cardiac) subunits. The high degree of conservation of this site among different K(ATP) channel isoforms suggests that this pathway may have wide significance for the physiological regulation of K(ATP) channels in various tissues and organelles.

Project description:Mitogen-activated protein kinases (MAPKs; ERK1/2, p38, JNK, and ERK5) have evolved to transduce environmental and developmental signals (growth factors, stress) into adaptive and programmed responses (differentiation, inflammation, apoptosis). Almost 20 years ago, it was discovered that MAPKs contain a docking site in the C-terminal lobe that binds a conserved 13-16 amino acid sequence known as the D- or KIM-motif (kinase interaction motif). Recent crystal structures of MAPK:KIM-peptide complexes are leading to a precise understanding of how KIM sequences contribute to MAPK selectivity. In addition, new crystal and especially NMR studies are revealing how residues outside the canonical KIM motif interact with specific MAPKs and contribute further to MAPK selectivity and signaling pathway fidelity. In this review, we focus on these recent studies, with an emphasis on the use of NMR spectroscopy, isothermal titration calorimetry and small angle X-ray scattering to investigate these processes.

Project description:Janus kinases (JAKs) mediate signal transduction downstream of cytokine receptors. Cytokine-dependent dimerization is conveyed across the cell membrane to drive JAK dimerization, trans-phosphorylation, and activation. Activated JAKs in turn phosphorylate receptor intracellular domains (ICDs), resulting in the recruitment, phosphorylation, and activation of signal transducer and activator of transcription (STAT)-family transcription factors. The structural arrangement of a JAK1 dimer complex with IFNλR1 ICD was recently elucidated while bound by stabilizing nanobodies. While this revealed insights into the dimerization-dependent activation of JAKs and the role of oncogenic mutations in this process, the tyrosine kinase (TK) domains were separated by a distance not compatible with the trans-phosphorylation events between the TK domains. Here, we report the cryoelectron microscopy structure of a mouse JAK1 complex in a putative trans-activation state and expand these insights to other physiologically relevant JAK complexes, providing mechanistic insight into the crucial trans-activation step of JAK signaling and allosteric mechanisms of JAK inhibition.